EC:2.7.11.22 - FACTA Search

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Query: EC:2.7.11.22 (cdc2)
8,319 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Many neurons in the developing nervous system undergo programmed cell death, or apoptosis. However, the molecular mechanism underlying this phenomenon is largely unknown. In the present report, we present evidence that the cell cycle regulator cyclin D1 is involved in the regulation of neuronal cell death. During neuronal apoptosis, cyclin D1-dependent kinase activity is stimulated, due to an increase in cyclin D1 levels. Moreover, artificial elevation of cyclin D1 levels is sufficient to induce apoptosis, even in non-neural cell types. Cyclin D1-induced apoptosis, like neuronal apoptosis, can be inhibited by 21 kDa E1B, Bcl2 and pRb, but not by 55 kDa E1B. Most importantly, however, overexpression of the cyclin D-dependent kinase inhibitor p16INK4 protects neurons from apoptotic cell death, demonstrating that activation of endogenous cyclin D1-dependent kinases is essential during neuronal apoptosis. These data support a model in which neuronal apoptosis results from an aborted attempt to activate the cell cycle in terminally differentiated neurons.
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PMID:Cyclin D1 is an essential mediator of apoptotic neuronal cell death. 859 5

By interacting with key regulatory proteins such as the pRb family, cyclins, cyclin-dependent kinases and p300/CBP of host cells, adenoviral E1A interferes with various cellular processes to provide a suitable environment for the replication of viruses. E1A may promote DNA synthesis and cell cycle progression, immortalize rodent cells in culture and transform cultured cells in cooperation with E1B, Ras, or other oncoproteins. Both extreme N terminus and conserved region 1 of E1A are required for the immortalization and the transformation of rodent cells, transcriptional repression and specific induction of the expression of cellular genes such as the proliferating cell nuclear antigen (PCNA) and heat shock protein 70 (HSP70). Although the molecular mechanisms of these functions of E1A are not fully understood, it is believed that protein-protein interactions may play essential roles. In this communication, we report that a new set of cellular proteins with apparent molecular weight of 200, 90, 45, 30, and 28 specifically associate with the extreme N terminus of E1A. Further analysis demonstrate that these associations do not depend on E1A's association with p300 or pRB. Neither the 30 kDa nor the 28 kDa polypeptide is identical to Cdc2 or Cdk2. The region of E1A required for the protein interaction is also required for the recently identified N-terminal transactivation activity of E1A. Our observations suggest that in addition to p300/CBP, the new set of cellular proteins may be involved in the functional complexity of the N terminus of E1A, thus predicting a p300/CBP independent pathway.
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PMID:Extreme N terminus of E1A oncoprotein specifically associates with a new set of cellular proteins. 900 47

It has previously been shown that following viral infection, Ad5 E1A induces cell cycle progression of quiescent rodent cells, leading to DNA synthesis and mitosis. Here we have examined the effect of Ad12 E1A on the cell cycle characteristics of human cells. Human tumor (A549, KB, and HeLa) cells were infected with Ad12 d/620, a mutant virus which has a lesion in the E1B gene and essentially expresses only E1A. These infected cells progressed from being largely in G1 into S phase, where they arrested. Even up to 96 h postinfection (p.i.) the cells remained blocked in S phase. DNA synthesis did, however, proceed in Ad12 d/620-infected cells, giving rise to multiple copies of cellular DNA. Similar results were obtained when primary human skin fibroblasts were infected, although the polyploidy was less marked. The expression of cyclins A, B1, and E in the tumor cells increased appreciably in response to E1A. In contrast, there was a dramatic reduction in the levels of cyclin D1 and D3. Increases in cyclin D1 expression could be detected at very late times p.i. In those cell lines expressing low levels of cdc2 and cdk2 an appreciable increase in expression was seen soon after Ad12 E1A could be detected. The elevated levels of cyclins A, B1, and E were associated with increased protein kinase activity directed against histone H1. An increase in cyclin D1-associated kinase activity against Rb1 was also observed at late times. This deregulation of the cell cycle was not solely dependent on E1A inactivation of Rb, since similar effects were seen in Ad12 d/620-infected retinoblastoma (Y-79) cells, implicating p107 and p130 in E1A-mediated changes in cell cycle progression. We propose that the E1A-induced levels of cyclins A, B1, and E by Ad12 E1A in human cells may lead to an uncoupling of S phase from cell cycle progression.
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PMID:Human cells arrest in S phase in response to adenovirus 12 E1A. 960 4

The p53 tumor suppressor protein regulates the transcription of regulatory genes involved in cell cycle arrest and apoptosis. We have reported previously that inducible expression of the p53 gene leads to the cell cycle arrest both at G(1) and G(2)/M in association with induction of p21 and reduction of mitotic cyclins (cyclin A and B) and cdc2 mRNA. In this study, we investigated the mechanism by which p53 regulates transcription of the cdc2 gene. Transient transfection analysis showed that wild type p53 represses whereas various dominant negative mutants of p53 increase cdc2 transcription. The cdc2 promoter activity is not repressed in cells transfected with a transactivation mutant, p53(22/23). An adenovirus oncoprotein, E1B-55K inhibits the p53-mediated repression of the cdc2 promoter, while E1B-19K does not. Since the cdc2 promoter does not contain a TATA sequence, we performed deletion and point mutation analyses and identified the inverted CCAAT sequence located at -76 as a cis-acting element for the p53-mediated regulation. We found that a specific DNA-protein complex is formed at the CCAAT sequence and that this complex contains the NF-Y transcription factor. Consistently, a dominant negative mutant of the NF-YA subunit, NF-YAm29, decreases the cdc2 promoter, and p53 does not further decrease the promoter activity in the presence of NF-YAm29. These results suggest that p53 negatively regulates cdc2 transcription and that the NF-Y transcription factor is required for the p53-mediated regulation.
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PMID:p53 negatively regulates cdc2 transcription via the CCAAT-binding NF-Y transcription factor. 1051 38

The signaling pathway leading to TGF-beta1-induced apoptosis was investigated using a TGF-beta1-sensitive hepatoma cell line, FaO. Cell cycle analysis demonstrated that the accumulation of apoptotic cells was preceded by a progressive decrease of the cell population in the G(1) phase concomitant with a slight increase of the cell population in the G(2)/M phase in response to TGF-beta1. TGF-beta1 induced a transient increase in the expression of Cdc2, cyclin A, cyclin B, and cyclin D1 at an early phase of apoptosis. During TGF-beta1-induced apoptosis, the transient increase in cyclin-dependent kinase (Cdk) activities coincides with a dramatic increase in the hyperphosphorylated forms of RB. Treatment with roscovitine or olomoucine, inhibitors of Cdc2 and Cdk2, blocked TGF-beta1-induced apoptosis by inhibiting RB phosphorylation. Overexpression of Bcl-2 or adenovirus E1B 19K suppressed TGF-beta1-induced apoptosis by blocking the induction of Cdc2 mRNA and the subsequent activation of Cdc2 kinase, whereas activation of Cdk2 was not affected, suggesting that Cdc2 plays a more critical role in TGF-beta1-induced apoptosis. In conclusion, we present the evidence that Cdc2 and Cdk2 kinase activity transiently induced by TGF-beta1 phosphorylates RB as a physiological target in FaO cells and that RB hyperphosphorylation may trigger abrupt cell cycle progression, leading to irreversible cell death.
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PMID:Cdc2 and Cdk2 kinase activated by transforming growth factor-beta1 trigger apoptosis through the phosphorylation of retinoblastoma protein in FaO hepatoma cells. 1054 99

The phosphorylation status of the pRB family of growth suppressor proteins is regulated in a cell cycle entry-, progression-, and exit-dependent manner in normal cells. We have shown previously that p130, a member of this family, exhibits patterns of phosphorylated forms associated with various cell growth and differentiation stages. However, human 293 cells, which are transformed cells that express the adenoviral oncoproteins E1A and E1B, exhibit an abnormal pattern of p130 phosphorylated forms. Here we report that, unlike pRB, the phosphorylation status of both p130 and p107 is not modulated during the cell cycle in 293 cells as it is in other cells. Conditional overexpression of individual G(1)/S cyclins in 293 cells does not alter the phosphorylation status of p130, suggesting that the expression of E1A and/or E1B blocks hyperphosphorylation of p130. In agreement with these observations, transient cotransfection of vectors expressing E1A 12S, but not E1B, in combination with pocket proteins into U-2 OS cells blocks hyperphosphorylation of both p130 and p107. However, the phosphorylation status of pRB is not altered by cotransfection of E1A 12S vectors. Moreover, MC3T3-E1 preosteoblasts stably expressing E1A 12S also exhibit a block in hyperphosphorylation of endogenous p130 and p107. Direct binding of E1A to p130 and p107 is not required for the phosphorylation block since E1A 12S mutants defective in binding to the pRB family also block hyperphosphorylation of p130 and p107. Our data reported here identify a novel function of E1A, which affects p130 and p107 but does not affect pRB. Since E1A does not bind the hyperphosphorylated forms of p130, this function of E1A might prevent the existence of "free" hyperphosphorylated p130, which could act as a CDK inhibitor.
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PMID:E1A blocks hyperphosphorylation of p130 and p107 without affecting the phosphorylation status of the retinoblastoma protein. 1070 33

The capability of REF cells transformed by EA + E1B-19 kDa and EA + cHa-ras oncogenes to realize the G1/S cell cycle arrest upon serum starvation was studied. The amount of cyclin-kinase inhibitor protein p27/Kip was shown to increase in both normal and transformed cells. However, the p27/Kip-bound cyclin-kinase complexes of transformed cells were found to be active, implying the functional inactivation of p27/Kip inhibitor. Nevertheless, in contrast to E1A + cHa-ras transformants, E1A + E1B-19 kDa transformants undergo the G1 cell cycle arrest. The G1 cell cycle block correlates with the decrease in cyclinE-Cdk2 activity. Since cyclinE-Cdk2 complexes need Thr-160 phosphorylation of Cdk2 by CAK-kinase for full activity, we have analysed the Cdk-7 associated activity upon serum starvation using gst-Cdk2 as a substrate. Serum starvation did not affect CAK activity either in E1A + cHa-ras or in E1A + E1B-19 kDa transformants. Thus, selective suppression of cyclineE-Cdk2 activity in E1A + E1B-19 kDa transformants upon serum starvation does not arise from the action of cyclin-kinase inhibitors, or from change in CAK activity.
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PMID:[Rat embryo fibroblasts transformed by complementation with oncogenes E1A+E1B-19 and E1A+cHa-ras differ in the ability to realize the G1/S block in serum free media]. 1184 Jul 77

Introduction of the E1A early region of the human adenovirus type 5 impairs the ability of mammalian cells to arrest the cell cycle at G1/S after damage. Two-parameter fluorescent-activated cell sorting (FACS) with iododeoxyuridine revealed the radiation-induced G1/S arrest in rat embryo fibroblasts transformed with the complementing E1A + E1B-19 kDa oncogenes. This was due to selective inhibition of CycIE/Cdk2-associated kinase activity, while activities of type 2 kinase and of CyclA/Cdk2 complexes remained unchanged. The inhibitor of G1-phase cyclin kinases, p21/Waf1, was accumulated and interacted with target kinases both in normal and in transformed cells after irradiation. As shown by immunoprecipitation, p21/Waf1 formed complexes with the E1A on coproducts in the transformants, which possibly accounted for its functional inactivation. Kinase modification in cyclin-kinase complexes was assumed to play a key role in regulation of cyclin-dependent kinases in the transformants with inactivated p21/Waf1.
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PMID:[Transfection with the E1A and E1B-19kDa oncogenes does not prevent rat embryo fibroblasts from cell cycle arrest after gamma-radiation]. 1186 14

Expression of human adenovirus type 5 E1A oncogene in normal rodent cells leads to disruption of the G1/S cell cycle arrest realization in response to DNA damage. It has been shown here that rat embryo fibroblasts transformed by E1Aad5 oncogene in complementation with E1B-19 kDa gene realize the irradiation-induced transient G1/S arrest, which depends on selective suppression of CyclinE-Cdk2 activity despite functional inactivation of p21Waf1 inhibitor. Inhibitor p21Waf1 is not revealed in complexes with cyclins E and A in E1A + E1B-19 kDa transformants, however, it is not due to p21Waf1 interaction with E1A oncoproteins, because the E1A-p21Waf1 complex formation in E1A + cHa-ras transformants does not prevent the high level of CycIE, A-p21Waf1 association. In the case of p21Waf1 inactivation, the main way of cyclin-kinase activity regulation in E1A + E1B-19 kDa cells may be Cdk2 phosphorylation. However, irradiation of E1A + E1B-19 kDa transformed cells induces no changes in CAK (Cdk7-associated) kinase activity and in the protein level of Cdc25A phosphatase, which are responsible for activating Thr160 phosphoralation and Tyr15 dephosphorylation on Cdk2. Using phospho-Tyr15-Cdk2 specific antibodies, no increase of phosphorylation at Tyr15 position on immunoprecipitated Cdk2 was detected after irradiation. It seems likely that in the case of inactivated inhibitor p21Waf1 the transient G1/S block after irradiation in E1A + E1B-19 kDa transformants depends on suppression of Cycl-E-Cdk2 activity caused by inhibition of Thr160 Cdk2 phosphorylation, but his occurs with the involvement of other kinases rather than CAK.
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PMID:[Analysis of transient G1/S arrest in E1A+E1B-19kDa transformed cells after ionizing radiation]. 1502 53

P21(Waf1) cyclin-dependent kinase inhibitor blocks cell cycle transition from G1 phase into DNA replication after DNA damage. The main targets of p21(Waf1) are Cyc 1E--Cdk2 and Cyc 1A--Cdk2 complexes, PCNA (proliferating cell nuclear antigen), a subunit of DNA polymerase delta, and E2F-1 transcription factor. The universal mechanism of cell cycle arrest in normal cells is determined as p21(Waf1) interaction with positive regulators of G1 phase. As a rule, DNA integrity control mechanisms are destroyed in the process of oncogenic transformation, which results in proliferation of genetically defective cells. The purpose of our study was to investigate molecular mechanisms of cell cycle regulation in transformants that are able (E1A + E1B-19kDa) or unable (E1A(+) + cHa-ras) to be arrested at G1/S checkpoint. We have shown that p21(Waf1) is able to form complexes with cyclins and Cdks, PCNA and E2F-1 transcryption factor, although it interacts with E1A oncoproducts in both transformants. The presence of E1A bound p21(Waf1) in cyclin-kinase complexes seems to be the cause of activating phosphorilation of Cdk2 at Thr-160 in cyclin A/E--Cdk2 complexes in both control and X-ray irradiated cells. Thus, the absence of G1/S arrest following irradiation in E1A + cHa-ras transformants and its presence in E1A(+) + E1B-19kDa transformants is not connected with differences in interaction of p21(waf1) with the main regulators of G1-to-S transition, but is realized through other not yet identified ways.
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PMID:[E1A oncogene effect on the ability of p21(Waf1) to regulate G1/S arrest in E1A-expressing transformants following irradiation]. 1670 94

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